Tag Archives: biology

The Role of Genetics in Athletic Ability

Posted on November 12, 2012 by | 1 comment

What exactly are genes?

A gene is a segment of DNA located on specific areas of the chromosomes that functions to control the production of proteins and directs the activities of cells. Every person has two copies of each gene; one copy comes from the father, and the other from the mother. Genes determine an individual’s characteristics such as hair color, eye color, and even ones athletic abilities. Specifically, genes have a large influence over strength, muscle size, muscle fiber composition, lung capacity, and flexibility.

Diagram of a gene. Showing a gene is a segment of DNA on a chromosome. Source: J.Craig Venter Institute

Moreover,  research indicates two specific genes, ATCN-3 and the ACE gene, have a very close relationship to the athletic performance of an individual.

What is the relationship between the ATCN-3 Gene and athletic performance?

The ATCN-3 gene is responsible for producing a protein called α-actinin-3. This protein is found in fast-twitch muscle fibers. The main function of this protein to generate intense muscle contractions during high velocity movements such as sprinting and weight lifting. There are two variants of the ACTN-3 gene. One is the R variant and the other is the X variantPower athletes usually have the R variant whereas endurance athletes have the X variant. Moreover, researchers have concluded that every Olympic level power athlete has a minimum of one copy of the ACTN-3 gene, and that it is impossible for someone to achieve top ranks in power sports without the gene. Also, another specific gene that determines an individual’s athletic potential is called the ACE gene.

This video by GeneTechPI explains in more detail the influence of ACTN-3 on physical performance:

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What is the relationship between the ACE Gene and athletic performance?

The basic function of the ACE gene is to regulate the rate of blood that flows throughout your body. The way in which this is accomplished is by first activating a hormone called angiotensin. Once this hormone is activated, it regulates the constriction of the blood vessels, and hence regulates the rate of blood flow. Individuals that have this gene are better endurance athletes, and respond a lot better to endurance training due greater efficiency of blood flow regulation. Moreover,  two variants exist, called the I and D variants. Rowers and long distance runners usually have the I variant, whereas power athletes like sprinters and weight lifters have the D variant.

So without the right genes, is it still possible to become a really good athlete?

With proper training and nutrition, you can get to a certain level but in the end genetics determine if you are capable of being an superstar athlete. It has been concluded by researchers that roughly 20-80% of athletic performance is related to genes. In fact, many Olympic level coaches believe that genetic testing should be an important component of the selection process in order to choose the very best athletes for their teams.

-Mandip Parmar

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Posted in Biological Sciences, Science Communication, Science in the News

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“Trust me, I’m an Engineer”

Posted on September 27, 2012 by | 2 comments

Ever seen the “Trust Me, I’m an Engineer” meme on the Internet? As it turns out, the slime mold Physarum polycephalum can claim the title of engineer as well!

Physarum polycephalum is a single-celled organism, which when in the plasmodium phase of the life cycle, will grow continuously, expanding tendrils into unknown territory, as long as nutrients are present.  Tendrils with high volumes of nutrients will expand, while those that are used less will gradually disappear, leaving an efficient network.

Fig 1: Physarum Polycephalum colony growing on a rock
Reproduced under a Creative Commons license from Wikipedia (original author: Jerry Kirkhart)

For background information on slime molds and their life cycle, click here.

Researchers in Japan and the UK experimented with slime mold, presenting it with a model where geographical locations of cities around Tokyo were represented by oat flakes. The slime mold was allowed to grow into the arena, creating a transport network. Amazingly, the network formed was comparable in efficiency to the real Tokyo rail system, even though the slime mold has no brain, no central planning process.

Here’s a video showing slime mold growing out into the Tokyo arena: (attribution: sjtkg001)

You say, wait a second, what exactly do the researchers mean by efficiency? 3 main factors were taken into account: total length (TL), average minimum distance (AMD) and fault tolerance (FT). Average minimum distance represents how easy it is to get between the food sources, which is analogous to how easy it is to get between cities (transport efficiency). Fault tolerance measures how resilient the network would be, i.e. if it still functions if connections are broken. A high-performing system is one with a low TL representing minimal cost, low AMD representing high transport efficiency, and high FT representing high resilience.

Here’s a podcast from CBC with Dr. Mark Fricker who headed the Tokyo rail slime mold experiment; he gives details on this experiment:

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If you’re suspicious that the slime mold got lucky, researchers replicated their experiment with transport networks in Germany, the UK and even Canada! They found that again, the slime mold built a network with comparable performance.

Here’s a link to an article testing slime mold growth with a trans-Canada highway model.

Drawing inspiration from the slime mold, researchers around the world are now using biological systems to model real-world infrastructure problems in arenas such as computing, transport, and communication. They take the real-world conditions of problems in these arenas, such as spatial boundaries (i.e. rivers, cities, mountains), and apply these boundary conditions on slime mold by manipulating variables such as light intensity and antibiotic concentration. They then observe the growth networks and patterns of slime mold that arise, and can use these as a preliminary model for a solution.

Interested in reading more? Researchers are also utilizing the slime mold to model the blood vessel networks feeding tumors. With this understanding, they hope to come up with a method to starve the tumor of blood by cutting off key connections.

-Christie Chan

References:

Tero, A., Seiji, T., Saigusa, T., Ito, K., Bebber, D.P., Fricker, M.D., Yumiki, K., Kobayashi, R., Nakagaki, T. (2010, January 22). Rules for biologically inspired adaptive network design. Science, 327, 439-442.

Video: https://www.youtube.com/watch?v=BZUQQmcR5-g

Websites used:

http://scienceblogs.com/notrocketscience/2010/01/21/slime-mould-attacks-simulates-tokyo-rail-network/

http://esciencenews.com/articles/2010/01/21/slime.design.mimics.tokyos.rail.system

http://news.sciencemag.org/sciencenow/2012/08/a-slimy-insight-into-treating-ca.html

Podcast:

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Posted in Biological Sciences

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Bacteria Are Mini Factories That Can Produce Fuels !

Posted on September 24, 2012 by | 3 comments

Have you ever thought about what would happen if you had to go to school or other places by walking or driving bicycle ? We become fearful even by thinking about this situation which happens when we run out of fossil fuels . Clearly, we are all dependent on fossil fuels to live comfortably.

However, it takes many years to produce enough fossil fuels by the decomposing plants.Furthermore, emissions through the combustion of fossil fuels contain harmful substances such as carbon dioxide which lead to global climate change.

Therefore,creating a new renewable energy source without unfavourable emissions is a serious issue to consider. One of the amazing solutions for this problem is achieved by using microbes to make advanced biofuels.

Microbes can produce biofuels.

(adapted from :http://web.mit.edu/press/2012/genetically-modified-organism-can-turn-carbon-dioxide-into-fuel.html)

Scientists in MIT university are trying to use a microbe called Ralstonia eutrophato to make fuel from carbon dioxide. Nitrate and phosphate are important nutrients for this bacterium , but when they are limited, it stores food by forming polymers out of the available carbon. The properties of these polymers are very similar to those of plastics made up of petroleum. By making a few changes to the bacterium’s genetic structure such as adding a new gene, removing a few genes and altering the expression of the other genes, scientists can produce fuel instead of plastic.More interestingly, they are trying to modify the microbe to use any waste product that is a source of carbon to make fuel.

Another advantage of using this microbe is that it automatically releases the isobutanol (a substitution for gasoline) which makes the process easier for the researchers.Fortunately, unlike some of the other biofuels , isobutanol can be used in car engines without any changes.

Up to this point, these scientists have been successful in making genetic changes that result in the production of isobutanol.

According to another study, animal fats and vegetable oils ,such as soybean oils, are commonly used as the raw material to produce biofuels. However, the increasing demand for biofuel production requires us to think of other biofuel sources which are suitable for human consumption. Microbial oils , such as the one discussed above, are better feedstocks for biofuel production rather than vegetable and animal oils due to different reasons : having shorter life cycle, requiring less work and increasing their amounts more easily.

Obviously, teaching microbes to make biofuels is a major breakthrough that is very beneficial and essential for all of the people around the world.

Below you can see a video that shortly explains about producing biofuels with the aid of microbes:

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video posted by “bloomberg”

Maryam Goharian

sources:

“MIT Media Relations”.

http://web.mit.edu/press/2012/genetically-modified-organism-can-turn-carbon-dioxide-into-fuel.html

“Biofuel definition “

http://en.wikipedia.org/wiki/Biofuel

“Global Climate Change” .http://www.cotf.edu/ete/modules/climate/GCclimate1.html

http://apps.webofknowledge.com.ezproxy.library.ubc.ca/full_record.do?page=1&qid=6&log_event=no&viewType=fullRecord&SID=2FnGmdEIaFKiJ3Mn25A&product=UA&doc=1&search_mode=GeneralSearch

https://www.youtube.com/watch?v=zBfjKYM9fLM

 

Picture from:

https://blogs.ubc.ca/communicatingscience2012w109/files/2012/09/biol200-image.jpg

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Posted in Biological Sciences

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